KR101835068B1 - Ball transporting device - Google Patents

Abstract

The present invention relates to a system for allowing a user, such as a golf practice system or a screen golf system, to strike a ball with a golf club to perform a golf swing, and aims to provide a ball transporting device, in which the ball struck by the user and blown is collected and transported to a batter so that the ball can be supplied, and especially, the straightness of the transport of the ball is maintained in the process of collecting and transporting the ball to prevent the friction between the ball and the device and reduce the abrasion and damage of the ball, thereby improving the reliability of the ball transport and supply. In addition, the present invention aims to provide the ball transporting device, which allows infiltrated foreign materials and the like to be effectively discharged during the transportation of the ball to prevent problems such as malfunction or breakage and the like, thereby improving the reliability of ball transport and supply.

Description

BALL TRANSPORTING DEVICE

The present invention relates to a ball transfer device for transferring a ball to a ball supply device for collecting a ball struck by a golf club by a user in a golf practice system, a screen golf system,

Recently, as the golf population has increased, a so-called screen golf system has come to be used in which golf practice using a virtual golf simulator or the like and a virtual golf game can be enjoyed.

In the screen golf system, a screen capable of displaying a virtual golf course is installed in the room. When a golfer hits the golf ball toward the screen, the screen golf system senses the speed and direction of the golf ball, .

As described above, the screen golf system implemented by the virtual golf simulation apparatus has a feature that it can give a sense of presence such as a round in a golf course while hitting the golf ball in the same manner as hitting the golf ball in the golf driving range.

Development of a ball supply system for allowing a ball to be automatically supplied to a batter for convenience of golfers in a virtual golf simulation environment such as the screen golf system as described above, Is required.

With respect to such a ball supply system, prior art documents such as Patent Publication No. 10-1262786, Registration Practical Utility Model No. 20-0430362, and Patent Document No. 2010-0009931 disclose a technology related to ball transfer have.

In this conventional ball transporting device, when the ball is transported and discharged by using a screw, the screw transports the ball from one side, so that the direction of the ball differs from the direction of the force of the screw, There was a frequent problem.

That is, when the ball is collected and the ball is transported by the ball transporting device, the ball is transported from one side by a screw or the like, so that the straightness of the transport until the ball is transported and discharged is not maintained properly, The ball is not worn or damaged due to the occurrence of severe friction due to the collision, or the ball transfer device for transferring the friction or wear of the ball or the damaged ball also causes malfunction or damage.

In addition, when foreign substances are infiltrated in the course of feeding the ball to the plate and the balls are caught due to any other reason, there is a problem that the apparatus malfunctions or the apparatus is damaged.

In a system in which a user, such as a golf practice system or a screen golf system, hits a ball to make a golf swing by hitting the ball, the ball blown by the user is collected and transported to the batter, In particular, it is possible to maintain the straightness of the ball transport during the process of ball collection and transportation, thereby preventing friction between the ball and the device, and reducing wear and damage of the ball, thereby improving the reliability of ball transportation and supply. So as to provide a ball transporting device.

It is another object of the present invention to provide a ball transporting device for improving the reliability of ball transport and supply by preventing infiltration of foreign substances or the like in the process of transporting the ball, thereby preventing malfunction or damage.

A ball transporting apparatus according to an embodiment of the present invention includes a casing having an inlet formed to be opened to allow a ball to be introduced thereinto and a discharge portion to which the ball introduced into the inlet flows to be discharged; A drive motor provided inside the casing; A first screw member which is provided in the casing and rotates to receive the rotational force of the driving motor to transfer balls to the discharge unit; And a second screw member that is provided substantially parallel to the first screw member and allows a ball placed between the first screw member and the first screw member to be transferred to the discharge unit.

Also preferably, the first screw member and the second screw member each have a screw vane and are rotated in opposite directions to each other and are positioned between the first screw member and the second screw member using the respective screw vanes And a drive screw member for transferring the balls to the discharge portion.

Preferably, the first screw member has a screw vane and rotatably provides a driving force for transferring the balls positioned between the first screw member and the second screw member to the discharge unit by using the screw vane And the second screw member is constituted as a supporting screw member configured to support the conveyance of the balls conveyed by the screw vanes of the first screw member.

Preferably, the first screw member is configured to include a first rotating shaft that rotates by receiving a rotational force of the driving motor, and a first screw blade provided along the longitudinal direction of the first rotating shaft, The second screw member may include a second rotation shaft receiving rotation force of the drive motor and rotating in a direction opposite to the first screw member and a second screw blade provided along the longitudinal direction of the second rotation shaft, And a ball positioned between the first screw member and the second screw member is configured to be transferred to the discharge unit by the first screw blade and the second screw blade while the first rotation axis and the second rotation axis rotate respectively .

Preferably, the first screw member includes a first rotating shaft that is rotated by receiving a rotational force of the driving motor, and a screw blade provided along the longitudinal direction of the first rotating shaft, Wherein the second screw member includes a second rotation shaft that receives rotation force of the driving motor and rotates in a direction opposite to the first rotation axis, and a second rotation shaft that rotates in a direction opposite to the first rotation axis, And a conveyance guide provided at an end portion of the discharge port side of the rotary shaft for conveying the ball to the discharge portion together with the first screw member.

Preferably, the first screw member includes a first rotating shaft that is rotated by receiving a rotational force of the driving motor, and a screw blade provided along the longitudinal direction of the first rotating shaft, And the second screw member is configured to transmit the rotation force of the driving motor to the first screw member in such a manner that the ball introduced into the inlet unit moves toward the first screw member, A second rotating shaft which is rotated by a screw blade of the first screw member to guide the ball to be transported by the screw wing of the first screw member and a second rotating shaft which is provided at an end portion of the discharging portion of the second rotating shaft, And a conveying guide configured to convey the ball together with the screw blade to the discharging unit.

Preferably, the conveying guide includes a spiral wing of one or two cycles opposite to the screw wing, so that a ball conveyed along the screw wing is conveyed to the discharge portion by the screw wing and the helical wing, .

Preferably, the driving force transmitting portion transmits the rotating force of the driving motor to the first rotating shaft, and the second rotating shaft transmits the rotating force of the first rotating shaft to the second rotating shaft, And a rotation direction switching section for rotating the rotation direction in the opposite direction.

Preferably, the rotation direction switching unit is configured such that a first gear connected to the first rotation shaft and a second gear connected to the second rotation shaft are engaged with each other, or an even number of connection gears are provided between the first gear and the second gear, Is formed to be engaged with each other.

Preferably, the plurality of rings are connected to the discharging portion, and a plurality of rings are fixed in parallel at predetermined intervals by a support, so that a ball discharged from the discharging portion passes through the plurality of rings to form a moving path, And a vibration rail configured to generate vibrations as it moves while applying pressure to the lower portions of the plurality of rings by the gravity.

Preferably, the guide bar is connected to the discharge portion, and the guide bar supporting the moving ball is guided by the fixing portion so that the balls discharged from the discharge portion move along the guide bar, A plurality of rings connected to the open rails and configured such that a plurality of rings are fixed side by side at predetermined intervals by a support so that balls passing through the open rails form a passage through which the plurality of rings pass And the vibrating rail is configured to generate vibration as the ball moves while applying pressure to the lower portions of the plurality of rings by gravity.

According to another aspect of the present invention, there is provided a ball transporting apparatus including: a casing having an inlet formed to be opened to allow a ball to be introduced therein and a discharge unit to which the ball introduced into the inlet flows to be discharged; A drive motor provided inside the casing; A drive screw member provided in the casing and adapted to receive the rotational force of the drive motor and rotate to transfer balls to the discharge unit; And a support screw member provided substantially parallel to the drive screw member and supporting the ball to be transported so as to maintain the straightness of the transport of the ball transported by the drive screw member.

Preferably, the driving screw member includes a driving rotation shaft that is rotated by receiving the rotational force of the driving motor, and a driving screw blade that is provided along the longitudinal direction of the driving rotation shaft, Wherein the support screw member is rotatably supported by a support rotation shaft provided substantially in parallel with the drive rotation shaft and a support rotation shaft provided at an end of the support rotation shaft at the discharge portion side, And a guide for guiding the driving screw member to transfer the ball to the discharge portion.

The ball transporting device according to the present invention is a system for allowing a user such as a golf practice system or a screen golf system to swing the golf ball by hitting the ball to swing the golf ball, In particular, it is possible to prevent the friction between the ball and the device by reducing the wear and damage of the ball by maintaining the straightness of the ball's transport during the process of collecting and transporting the ball, Is improved.

In addition, it is possible to effectively discharge impregnated foreign substances or the like in the process of transporting the ball, thereby preventing problems such as malfunction or breakage, thereby improving the reliability of ball transport and supply.

FIG. 1 is a schematic view illustrating a state where a ball transporting apparatus according to an embodiment of the present invention is applied to a screen golf system.
Fig. 2 is a view showing a configuration of a ball supply system including the ball transporting apparatus shown in Fig. 1. Fig.
3 is a plan view of the ball transport apparatus according to the embodiment of the present invention in which the upper end of the casing is separated.
4 is a front view of the ball transporting apparatus shown in Fig.
5 and 6 are views showing the configuration of a ball transporting device according to another embodiment of the present invention, respectively.
7 is a more detailed view of the open rails and the vibrating rails shown in Figs. 3-6.

A more detailed description of the ball transporting apparatus according to the present invention will be described with reference to the drawings.

First, a ball transporting apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG.

FIG. 1 is a schematic view showing a state where a ball transporting apparatus according to an embodiment of the present invention is applied to a screen golf system, FIG. 2 is a view showing a configuration of a ball supply system including the ball transporting apparatus shown in FIG. 1 Fig.

As shown in FIG. 1, a screen 30 on which a virtual golf simulation image is projected is provided on the front of a screen golf booth, and a golf club 20 is mounted on the floor 10, A golf mat 22 on which the golf ball 1 is placed and a sensing device for sensing the hit of the ball by the golfer, not shown in the figure.

In addition, a simulator (S) is provided at one side of the booth for performing predetermined data processing for virtual golf simulation according to a result of sensing in the sensing device to implement a simulation image to be projected onto the screen (30).

The ball transfer device 100 of the ball supply system according to the embodiment of the present invention is installed in an installation space 50 formed below the floor 10 of the booth and is provided between the screen 30 and the floor 10, A ball 1 hit by a golfer is formed so that the ball 30 can hit the screen 30 and roll down along the inclined surface 32 to move to the ball transfer device 100 in the installation space 50.

In addition, it is preferable that the cover plate 52 covers the installation space 50 so that the ball transport device 100 is protected.

Meanwhile, a space of a predetermined size is provided under the plate 20, and a ball supply device 500 of a tee-up type is installed in the space, and the ball is automatically supplied to the golf mat 22 .

1, a ball feeding system (including a ball feeding apparatus, a feed connecting tube, and a ball feeding apparatus) including a ball feeding apparatus 100 includes a ball feeding apparatus 100 and a ball feeding apparatus 500, And the ball transported by the ball transport apparatus 100 moves along the transport connection pipe 300 and is transported to the ball supply apparatus 500.

It is preferable that the transfer connection pipe 300 is embedded under the floor 10 so as not to be exposed to the outside.

2 shows a more specific configuration of the ball transport device 100, the transport connection pipe 300, and the ball supply device 500. As shown in FIG.

2, the ball transporting apparatus 100 includes an inlet 103 formed to be opened to allow the ball 1 to flow into one side thereof, and a discharge unit (not shown, not shown) through which the ball is discharged to the other side And a screw member (not shown) and the like are provided in the casing 101 in which the casing 101 is formed, and a driving motor (not shown) and a screw member (not shown)

A guide plate 104 is provided in the inflow portion 103 to guide the inflow of the ball 1 into the inflow portion 103. The ball 1 introduced into the inflow portion 103 is a screw member (Not shown), and is transported to the ball feeding device 500 along the transporting connection pipe 300. The ball transporting device 300 shown in FIG.

The ball transporting apparatus 100 includes an opening rail 210 and a vibration rail 220 for connecting a discharge unit (not shown) of the casing 101 and the transport connection pipe 300, And the foreign matter that is buried in the ball 1 or sandwiched between the ball and the ball can be removed while passing through the open rail 210 and the vibration rail 220 in order.

Although the open rail 210 and the vibration rail 220 are shown together in the drawing, foreign matter removal from the ball can be effectively performed even if only the open rail 210 or only the vibration rail 220 is provided. Of course, when the opening rail 210 and the vibration rail 220 are used together, it is of course possible to obtain a more reliable effect of removing foreign matter.

The transfer connection pipe 300 connects the ball transfer device 100 and the ball supply device 500 to form a path through which the ball is transferred. The transfer connection pipe 300 is filled with balls, The apparatus 100 discharges the balls 1, thereby transferring the filled balls to the ball feeding apparatus 500 while being pushed.

The ball supply device 500 is a device for supplying balls by making the ball 1 tee up. The ball supply device 500 includes a tee member 510, and a ball supply driver 520 drives the tee member 510 So that the ball supply is performed by raising or lowering in the vertical direction.

The transfer connection pipe 300 is connected to the connection portion 502 of the ball supply device 500 to transfer the ball into the ball supply device 500. When the transferred ball is seated on the tee member 510, The driving unit 520 raises the tee member 510 so that the ball is supplied to the golfer.

3 and 4, the detailed configuration and operation of the ball transporting apparatus according to an embodiment of the present invention will be described in more detail.

3 is a plan view of the ball transporting apparatus 100 according to an embodiment of the present invention in which the upper end of the casing 101 is separated and FIG. 4 is a front view of the ball transporting apparatus 100 shown in FIG. 3 .

3 and 4, a ball transporting apparatus 100 according to an embodiment of the present invention includes an inlet 103 through which a ball flows and a casing through which a ball discharges 106 A first screw member 120, a second screw member 130, and the like.

The ball transporting device according to an embodiment of the present invention includes a first screw member 120 and a second screw member 130 which are disposed substantially parallel to each other at a predetermined distance from each other as transporting means for transporting the recovered balls So that the balls positioned between the first screw member 120 and the second screw member 130 can be transferred stably while maintaining the linearity of the transfer.

The first screw member and the second screw member can be constituted as a driving screw member as one means for providing a driving force for substantially conveying the ball and as a supporting screw member for supporting the ball to be conveyed.

That is, the first screw member includes a screw vane and is configured as a drive screw member for providing a driving force for rotating the ball located between the first screw member and the second screw member to the discharge unit by using the screw vane by rotation And the second screw member is constituted as a support screw member for supporting the conveyance of the balls conveyed by the screw vanes of the first screw member, so that the two screw members can stably convey the ball to the discharge portion while maintaining the linearity.

In this case, the first screw member, which is implemented as a driving screw member, receives a rotational force from the driving motor to generate a driving force for ball transport, and a second screw member, which is implemented as a supporting screw member, It may be implemented only to be able to rotate without being received.

In addition, the first screw member and the second screw member may be configured as a drive screw member for transferring balls together with a driving force. That is, the first screw member and the second screw member each have screw vanes and are rotated in opposite directions to each other, and the balls positioned between the first screw member and the second screw member are transferred to the discharge unit by using the respective screw vanes .

The first screw member 120 and the second screw member 130 which are applied to the ball transporting apparatus according to the embodiment shown in Figs. 3 and 4 are arranged such that the first screw member 120 is formed as the above- And the second screw member 130 is embodied as the support screw member described above.

Needless to say, the support screw member does not provide any driving force at the time of transporting the ball, and the second screw member 130 receives the rotational force from the driving motor to provide a driving force when the ideal ball is rotated But the primary function is to support the ball being transported by the first screw member 120.

3 and 4, a ball transporting apparatus according to an embodiment of the present invention includes a casing 101 and a drive motor 110. The first and second screw members 120 and 120, And the rotational force of the driving motor 110 is transmitted to the first screw member 120 by the rotational force transmitting part 150. The rotational force of the driving motor 110 is transmitted to the first screw member 120, And may be configured to be transmitted to the second screw member 130 by the rotation direction switching unit 160.

The first screw member 120 includes a first rotating shaft 121 that is rotated by receiving the rotational force of the driving motor 110 by the rotational force transmitting unit 150 and a second rotating shaft 121 which is rotated along the longitudinal direction of the first rotating shaft 121 And a screw blade 122 formed by a plurality of helical blades SB. One end of the screw blade 122 is connected to the rotational force transmitting part 150 and the other end is rotatably mounted on the discharge part 106 side.

3, the screw vanes 122 formed along the longitudinal direction of the first rotation shaft 121 of the first screw member 120 are formed in a plurality of periods T as shown in FIG. .

As shown in FIG. 3, one period T is formed by turning a helical blade SB about a turn in a spiral direction along the first rotation axis 121, and the screw blade 122 of the first screw member 120 Has a plurality of spiral wings SB of a period T and the ball 1 is seated on the spiral sliver SG between the spiral wings SB so as to discharge the spiral wings SB along the direction in which the screw wings 122 rotate And is transported toward the portion 106. [ 3, the second rotation shaft 131 of the second screw member 130 is disposed parallel to the first screw member 120 at a predetermined interval. As described above, So that it can be supported on the sled SG and conveyed.

The second screw member 130 receives the rotational force of the driving motor 110 by the rotational direction switching unit 160 and rotates in a direction opposite to the first rotational shaft 121 of the first screw member 120 The second rotation shaft 131 is provided substantially parallel to the first rotation shaft 121 (one end is connected to the rotation direction switching unit 160 and the other end is fixed to be rotatable to the discharge unit 106) And a conveyance guide 132 formed as a spiral blade at an end of the second rotation shaft 131 on the side of the discharge portion 106. [

3, the second screw member 130 rotates in a direction to allow the ball 1, which flows into the inlet portion 103 of the casing 101, to move toward the first screw member 120, So that the ball 1 introduced into the inlet 103 is brought into contact with the second rotation shaft 131 of the second screw member 130. When the second rotation shaft 131 rotates as described above, May move toward the first screw member 120 in accordance with the rotation of the second rotation shaft 131. [

The second rotary shaft 131 of the second screw member 130 supports and guides the ball 1 by the screw vane 122 of the first screw member 120 to guide the discharge unit 106, So that it can be transported stably while maintaining the straightness.

As shown in FIG. 3, the second screw member 130 may include a conveying guide 132 at an end of the second rotating shaft 131 on the side of the discharging portion 106.

The conveying guide 132 is supported such that the first screw member 120 can be stably discharged through the discharging unit 106 while maintaining straightness of the ball being conveyed from the discharging unit 106 side while the ball is being conveyed, It also provides driving force to be easily transported.

The conveying guide 132 is provided at an end of the second rotating shaft 131 on the side of the discharging portion 106 and is connected to the discharging portion 106 while conveying the ball 1 together with the screw blade 122 of the first screw member 120. [ It is possible to realize any shape as long as it can function as a guide for guiding the light beam.

3, a spiral blade corresponding to one period T is formed at the end portion of the second rotation shaft 131 as the transport guide 132. In FIG. In addition, the helical wings may be the same as the screw wings 122 of the first screw member 120, and the spiral direction of the helical wings may be reversed.

As described above, the helical wings, which are the end portions of the screw wings 122 of the first screw member 120 and the helical wings of the transfer guide 132 of the second screw member 130, The ball 1 is pushed into the discharge portion 106 as if it is wrapped with both hands so that the ball 1 can be stably discharged while minimizing the friction.

Although FIG. 3 illustrates the case where the transport guide 132 is implemented as a spiral blade of one period T, it may be implemented as a spiral blade of two cycles. However, when the section of the conveying guide 132 is long, it is preferable that the conveying guide 132 is formed in a section that does not disturb the inflow of the ball, Do.

3, reference numeral 133 denotes a rear portion provided at the rear end of the second rotation shaft 131 to prevent the ball from deviating toward the rear end thereof.

The rotational force transmitting portion 150 and the rotational direction switching portion 160 shown in FIG. 3 will be described in more detail.

3, the rotational force transmitting portion 150 of the ball transporting apparatus according to an embodiment of the present invention includes a first pulley (not shown) connected to a motor shaft of a driving motor 110 provided inside a casing 101, 151 and a second pulley 152 connected to the first rotation shaft 121 of the first screw member 120 and the first and second pulleys 151 and 152 are connected and rotated together, And a connecting member 153 for transmitting the rotational force of the first screw member 120 to the first rotating shaft 121 of the first screw member 120.

The connecting member 153 may be formed of a belt or a chain that simultaneously rotates the first pulley 151 and the second pulley 152, It is also possible to use a plurality of gears instead of the pulleys and the second pulleys. In the case of implementing gears, for example, gears may be fixed to the motor shaft and the first rotation shaft, respectively, and intermediate gears may be interposed therebetween to rotate the motor shaft and the first rotation shaft in the same direction. It is also possible to drive the driving motor in the opposite direction by directly engaging the two gears.

3, the rotation direction switching unit 160 may include a first gear G1 connected to the first rotation shaft 121 and a second gear G1 connected to the second rotation shaft 131, Two gear shafts Sa and Sb are provided between the two gears G2 and gears Ga and Gb are provided on the respective gear shafts so that four gears G1, Ga, Gb and G2 are engaged with each other .

As a result, the first rotary shaft 121 rotates in a forward direction by the rotational force transmitted from the drive motor 110 through the rotary force transmitting portion 150, the first gear G1 rotates the Ga gear in the reverse direction, The Gb gear is rotated in the forward direction again and the Gb gear rotates the second rotation shaft 131 in the opposite direction while rotating the second gear G2 so that the first rotation axis 121 and the second rotation axis 131 rotate in opposite directions As shown in Fig.

Here, c1, ca, cb and c2 denote shrinkage portions, c1 and c2 fix the first and second rotation shafts 121 and 131, respectively, and ca and cb respectively fix the shafts Sa and Sb.

By using the four gears G1, Ga, Gb and G2 as described above, the first screw member 120 and the second screw member 130 can be driven so as to rotate in opposite directions to each other. For example, the first gear G1 and the second gear G2 may be engaged with each other, or by arranging an even number of gears such as two, four, etc. between the first and second gears G1 and G2, And the rotation direction of the second screw member 130 may be opposite to each other.

3, if the rotational direction of the second screw member 130 is in the same direction as that of the first screw member 120, the ball 1 is rotated by the rotation of the second rotational shaft 131, The first screw member 120 and the second screw member 130 are prevented from flowing inwardly of the first screw member 130 and the conveying guide 132 may interfere with the straight advance of the ball 1, It is preferable to configure such that it rotates.

3 and 4, the ball transporting apparatus according to one embodiment of the present invention includes an opening rail 210 installed to be connected to the discharge portion 106 of the casing 101, ). ≪ / RTI >

As described above, when the ball 1 is discharged through the discharge part 106 by the first screw member 120 and the second screw member 130, as shown in FIGS. 3 and 4, Passes through the rail 210, passes through the vibration rail 220, and enters the transfer connection pipe (not shown).

The ball 1 discharged through the discharging portion 106 may pass through the opening rail 210 and the vibration rail 220 in order and foreign substances or the like attached to the ball 1 may be discharged to the outside. Specific details will be described later.

A connecting portion 228 may be formed at a rear end of the vibrating rail 220 to connect the feeding connection pipe 300 (see FIG. 2).

5, a ball transporting apparatus according to another embodiment of the present invention will be described.

The ball transporting apparatus according to the embodiment shown in FIG. 5 is basically a form in which the rotation direction switching unit 160 is omitted in the ball transporting apparatus according to the embodiment shown in FIG.

In other words, the ball transporting device according to the embodiment shown in FIG. 5 is configured such that only the first screw member is rotated by the drive motor, and the second screw member is provided so as to be rotatable only without receiving rotational force from the drive motor.

In the ball transporting apparatus according to the embodiment shown in Fig. 3, the first screw member 120 is the main driving means of the ball, but the second screw member 130 has also provided some driving force for transporting the ball The screw member 130 also indirectly receives the rotational force of the driving motor and rotates.

However, in the ball transporting apparatus according to the embodiment shown in FIG. 5, the transporting and driving means of the ball is one screw member and the other screw member supports the transporting of the balls so as to maintain the straightness of the transport of the balls Role.

Therefore, in the present embodiment, the first screw member and the second screw member described above will be described using the terms driving screw member and supporting screw member.

5, the ball transfer device according to the present embodiment transfers the rotational force of the driving motor 110 through the rotational force transmitting portion 150, and conveys the ball 1 toward the discharge portion 106 while rotating And a support screw member 130a disposed to be spaced apart from the drive screw member 120a by a predetermined distance and disposed substantially parallel to the drive screw member 120a.

The driving screw member 120a includes a driving rotation shaft 121a rotated by receiving the rotational force of the driving motor 110 and a driving screw blade 122a provided along the longitudinal direction of the driving rotation shaft 121a The drive shaft 122a rotates and the ball 1 is transferred to the discharge unit 106 while the drive rotation shaft 121a rotates.

The support screw member 130a includes a support rotation shaft 131a which is rotatably provided substantially parallel to the drive rotation shaft 121a and a support shaft 131b which is provided on the end of the support rotation shaft 131a on the discharge portion side And a support guide 132a for guiding the drive screw member 120a to transport the ball 1 to the discharge portion 106. [

The structure of the driving screw member 120a is substantially the same as that of the first screw member 120 shown in Fig. 3, and the structure of the supporting screw member 130a is the same as that of the second screw member 120a shown in Fig. 130a. Therefore, a detailed description of the structure itself of both screw members is the same as that described with reference to FIG. 3, and a description thereof will be omitted.

In the ball transporting apparatus according to the embodiment shown in FIG. 5, while the drive screw member 120a transports the ball, the support screw member 130a supports the linearity thereof, and reaches the support guide 132a, Is rotated together by friction with the balls 1 to guide the balls to be discharged.

3, the rotational direction switching unit can be omitted. Therefore, compared with the ball transferring apparatus according to the embodiment shown in FIG. 3, There is an advantage in that it can be made smaller or it is not necessary to install a large number of gears.

Since other components not described in FIG. 5 are the same as those described in FIG. 3, the description thereof will be omitted.

6, a ball transporting apparatus according to another embodiment of the present invention will be described.

The ball transporting device according to the embodiment shown in Fig. 6 has a large difference in the second screw member as compared with the ball transporting device according to the embodiment shown in Fig. 3 described above.

That is, in the embodiment shown in FIG. 3, the second screw member has a structure in which the long section is provided only by the rotation shaft without the helical wing, and the conveying guide is formed by the helical wing only in the short section of the discharge section. In the embodiment, the second screw member 140 has substantially the same structure as that of the first screw member 120, and the direction of rotation of the helical blade is reversed.

That is, the ball transporting apparatus according to the present embodiment is provided with the first screw vane 122 so that the first screw member 120 forms the spiral vane SB and the spiral vine SG with the first rotation shaft 121 The second screw member 140 is constituted by a helical blade SB in the opposite direction to the second rotation shaft 141 and a second screw blade 142 forming the helical valley SG.

The spiral blade SB of the first screw blade 122 and the period T of the helical blade SB of the second screw blade 142 are made to be substantially equal to each other so as to be symmetrical to each other, .

The ball transport apparatus according to the embodiment shown in Fig. 6 thus has a spiral wing SB between spiral wings SB of a plurality of periods T formed in the first screw wing 122 of the first screw member 120 The ball 1 is inserted into the helical valley SG between the spiral wings SB of the plurality of periods T formed in the second screw vanes 142 of the first screw member SG and the corresponding second screw member 140, So that the first screw vane 122 and the second screw vane 142 are transferred to the discharge portion 106 along the direction of rotation.

The first screw vane 122 of the first screw member 120 and the second screw vane 142 of the second screw member 140 rotate in opposite directions to each other, The balls are transferred to the discharging unit 106 while being rotated.

However, in this case, the inlet portion formed in the casing 101 can not be in the lateral direction. This is because the inflow of the ball through the inlet can be disturbed by the screw blade 142 of the second screw member 140.

6, the ball inlet 103u may be formed at the upper end of the casing 101 so that the ball to be recovered may be inserted into the ball inlet (not shown) of the upper end of the casing 101 103u to flow between the first screw member 120 and the second screw member 140.

Other elements not described in FIG. 6 are the same as those described in FIG. 3, so a description thereof will be omitted.

7, the opening rail 210 and the vibration rail 220 shown in FIG. 3 and the like will be described in more detail.

7 (a) shows the construction of the above-described open rail 210 and the vibration rail 220, and FIG. 7 (b) shows a state in which the ball passes through the open rail 210 and the vibration rail 220 Respectively.

The opening rail 210 is connected to the discharging portion 106 of the casing 101 and the guide bar 212 for supporting the moving ball and guiding the moving is fixed by the fixing portion, So that the discharged balls move along the guide bar 212 and the guide bars 212 are opened.

Accordingly, the balls passing through the opening rails 210 can discharge foreign substances or the like through the open portions between the guide bars 212.

Meanwhile, the ball passing through the opening rail 210 passes through the vibration rail 22 and generates vibration by friction, thereby enabling foreign substances and the like on the balls to be more positively discharged.

The vibrating rail 220 is connected to the open rail 210 and a plurality of rings 222 are fixed at predetermined intervals by a support base 221 so that the balls 1 passing through the open rail 210, Passes through the plurality of rings 222 and forms a passage through which the ball 1 moves so that the ball 1 moves under pressure by applying a load to the lower portions of the plurality of rings 222, It is possible to effectively remove small foreign substances on the ball 1 due to the vibration.

That is, in the portion A in FIG. 7 (b) and the enlarged cross-sectional view of the portion A, when the ball 1 passes over the plurality of rings 222, the ball 1 moves in the advancing direction d of the ball 1 The force is applied to the lower ends of the plurality of rings 222 by a force in the direction of the force and the load W and the balls progress as if the respective rings 222 are bounced by the force, ) Is jittery, but vibration occurs.

Such weak vibrations provide sufficient energy to remove small particles of foreign matter from the ball.

Thus, the ball transport apparatus according to an embodiment of the present invention allows a ball to pass through the open rail 210 and the vibration rail 220 in order, removing foreign matter from the open rail 210, Since the balls are transported while removing the foreign substances actively and removing the foreign substances in a double manner, it is possible to effectively remove the foreign substances caused by the penetration from the outside or the friction of the balls during the ball transporting process.

Although the open rail 210 and the vibrating rail 220 are sequentially used together in the above-described embodiments, the ball transporting device according to the present invention is not limited thereto, and only the open rail 210 But it is also possible to use the vibration rail 220 alone.

100: ball transport device, 101: casing
103: inlet portion, 106:
110: drive motor, 120: first screw member
121: first rotating shaft, 122: screw blade
130: second screw member, 131: second rotating shaft
132: conveying guide, 150:
160: rotation direction switching unit, 210: opening rail
220: Vibration rail, 300: Feed connection pipe

Claims (13)

A casing having an inlet formed to be opened to allow the ball to flow therein and a discharge portion to which the ball introduced into the inlet flows to be discharged;
A drive motor provided inside the casing;
A first screw member which is provided in the casing and rotates to receive the rotational force of the driving motor to transfer balls to the discharge unit; And
A second screw member provided substantially parallel to the first screw member to allow a ball placed between the first screw member and the first screw member to be transferred to the discharge unit;
And the ball transporting device. The method according to claim 1,
Wherein the first screw member and the second screw member each have a screw vane and are rotated in directions opposite to each other so that a ball positioned between the first screw member and the second screw member is discharged to the discharge portion And a drive screw member for transferring the balls. The method according to claim 1,
Wherein the first screw member is a drive screw member having a screw vane and using a screw vane by rotation to provide a driving force for transferring a ball positioned between the first screw member and the second screw member to the discharge unit And,
Wherein the second screw member is configured as a support screw member configured to support the transport of the balls being carried by the screw vanes of the first screw member. The method according to claim 1,
Wherein the first screw member comprises:
A first rotating shaft which is rotated by receiving a rotational force of the driving motor and a first screw blade which is provided along a longitudinal direction of the first rotating shaft,
Wherein the second screw member comprises:
A second rotation shaft which receives rotation force of the driving motor and rotates in a direction opposite to the first screw member, and a second screw blade which is provided along a longitudinal direction of the second rotation shaft,
And a ball positioned between the first screw member and the second screw member is configured to be transferred to the discharge unit by the first screw blade and the second screw blade while rotating the first rotation shaft and the second rotation shaft, respectively Ball transporting device. The method according to claim 1,
Wherein the first screw member comprises:
A first rotating shaft which is rotated by receiving a rotational force of the driving motor and a screw blade which is provided along a longitudinal direction of the first rotating shaft, the screw shaft rotates while the first rotating shaft rotates, Lt; / RTI >
Wherein the second screw member comprises:
A second rotation shaft which is received in a rotational direction of the driving motor and rotates in a direction opposite to the first rotation axis, and a second rotation shaft which is provided at an end portion of the second rotation shaft on the discharge side to transfer the balls together with the first screw member to the discharge portion And a transporting guide for transporting the recording medium. The method according to claim 1,
Wherein the first screw member comprises:
A first rotating shaft which is rotated by receiving a rotational force of the driving motor and a screw blade which is provided along a longitudinal direction of the first rotating shaft, the screw shaft rotates while the first rotating shaft rotates, Lt; / RTI >
Wherein the second screw member comprises:
A second rotating shaft which is rotated in a direction to receive the rotational force of the driving motor and moves the ball introduced into the inflow portion toward the first screw member and guides the ball by the screw blade of the first screw member, And a conveyance guide provided at an end portion of the second rotary shaft on the discharge side so as to transfer the balls conveyed by the screw vanes of the first screw member to the discharge portion together with the screw vane. Conveying device. 7. The apparatus according to claim 5 or 6,
Wherein the ball is conveyed to the discharge unit by the screw blade and the helical wing, the ball being conveyed along the screw blade including one or two cycles of helical wings in the opposite direction to the screw blade. . 7. The method according to any one of claims 4 to 6,
A rotational force transmitting portion for transmitting the rotational force of the driving motor to the first rotational shaft and a second rotational shaft for transmitting the rotational force of the first rotational shaft to the second rotational shaft and rotating the second rotational shaft in a direction opposite to the rotational direction of the first rotational shaft Further comprising: a rotation direction switching unit for switching the rotation direction of the ball. 9. The apparatus according to claim 8,
Wherein a first gear connected to the first rotation shaft and a second gear connected to the second rotation shaft are engaged with each other or an even number of connection gears are engaged between the first gear and the second gear. Device. The method according to claim 1,
Wherein the ball is connected to the discharge portion and is configured such that a plurality of rings are fixed side by side at a predetermined interval by a support member so that a ball discharged from the discharge portion passes through the plurality of rings to form a moving path, Further comprising a vibration rail configured to generate vibration as it moves while applying pressure to the lower portions of the plurality of rings. The method according to claim 1,
A guide bar which is connected to the discharge part and supports a moving ball and is fixed by a fixing part to guide movement of the ball so that a ball discharged from the discharge part moves along the guide bar, The rail,
Wherein the ball is connected to the open rail and is configured such that a plurality of rings are fixed side by side at a predetermined interval by a support so that a ball having passed through the open rail passes through the plurality of rings to form a moving path, Further comprising a vibration rail configured to generate vibration as it moves while applying pressure to the lower portions of the plurality of rings. A casing having an inlet formed to be opened to allow the ball to flow therein and a discharge portion to which the ball introduced into the inlet flows to be discharged;
A drive motor provided inside the casing;
A drive screw member provided in the casing and adapted to receive the rotational force of the drive motor and rotate to transfer balls to the discharge unit; And
A supporting screw member provided substantially parallel to the driving screw member and supporting the ball to be conveyed so as to maintain the straightness of conveyance of the ball conveyed by the driving screw member;
And the ball transporting device. 13. The method of claim 12,
The drive screw member
And a driving screw vane provided along a longitudinal direction of the driving rotation shaft, the driving screw vane is rotated while the driving rotation shaft is rotated to transfer balls to the discharging portion Lt; / RTI >
Wherein the support screw member comprises:
And a support guide provided at an end portion of the discharge rotary shaft of the support rotary shaft for guiding the drive screw member to transfer the ball to the discharge portion Characterized by a ball transport device.

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